Monitoring the uptake of live avian vaccines by their detection in feathers.

Protection against diseases caused by the avian viruses, Marek's disease, Infectious laryngotracheitis, chicken anemia and turkey meningoencephalitis is achieved by live vaccines. The application quality is important to assure proper uptake in commercial flocks. We describe a novel evaluation method for the vaccination process by sequential monitoring the vaccine viruses in feathers. Feather collection is easy, non-invasive and non-lethal for the birds, therefore advantageous for monitoring purposes. To demonstrate the vaccine virus presence, an innovative assay of nested real-time amplification was approached because vaccine viruses presence in vivo is less abundant comparing to virulent wild-type isolates. The Marek's disease virus vaccine virus, Rispens/CVI988, in feathers of commercial flock was detected from 4 to 7 days and for at least 3 months post-vaccination, until the survey stopped. As the drinking water route was newly adopted for Infectious laryngotracheitis vaccination, one or two vaccine doses/bird were administered. The virus uptake was detected in feathers between 2 and 20 days-post-vaccination. With a doubled vaccine dose the positivity bird rate was higher. For the first time the chicken anemia vaccine virus presence in chicken feathers was demonstrated between 14 and 35 days-post-vaccination. No previous studies were available, thus in parallel to feathers the vaccine virus was demonstrated in the livers and spleens. The turkey meningoencephalitis vaccine virus uptake in turkey feather-pulps is even more innovative because this is the first turkey virus amplified from feather-pulps. The vaccine virus presence resemble the kinetics of the other 3 viruses, 3-21 days-post-vaccination. Detecting the specific antibodies following vaccination possessed a lower sensitivity than vaccine virus demonstration in feathers. In summary, the presented assay can be adopted for the quality evaluation of the vaccination process in poultry.

Differential amplification of Marek's disease CVI988 vaccine and of wild-type isolates from organs of commercial chickens using single or duplexed probes in real-time PCR.

The differentiation of Marek's disease virus (MDV)-infected and vaccinated animal (DIVA) test, based on the MDV pp38 gene was described by Baigent et al. [(2016). Real-time PCR for differential quantification of CVI988 vaccine and virulent MDV strains. Journal of Virological Methods, 233, 23-36], using similar primers and alternate probes for virulent MDV-1 and the vaccine CVI988 virus. We explored the assay's applicability for commercial vaccines and commercial chickens, as the above-mentioned study employed tissue-cultured MDV strains and tissues from experimental trials. DNA of visceral organs and feathers of vaccinated or naturally infected chickens was used. Further, the applicability of the DIVA assay was evaluated using single or duplexed probes for the two viruses in the same amplification tube. Due to the high viral content in the commercial vaccines and in the clinical cases of MDV-1 infected commercial chickens, their examination by the MDV-1 DIVA real-time PCR was performed in one step. However, for the feather DNAs of commercially vaccinated birds, a step of pre-amplification was required. The MDV-1 DIVA real-time PCR performed as single probe in separate tubes using the Vir3 probe was very sensitive for virulent MDV-1 strains, but not very specific, as it also gave a clear signal with CVI988 vaccine virus. In contrast, the CVI vaccine probe was specific for CVI988, and did not recognize the MDV-1 strains. When both probes were present in one tube, the CVI probe showed a greater sensitivity for CV1988, while the Vir3 probe showed a much better specificity for virulent MDV-1.

Development of duplex dual-gene and DIVA real-time RT-PCR assays and use of feathers as a non-invasive sampling method for diagnosis of Turkey Meningoencephalitis Virus.

The avian flavivirus Turkey Meningoencephalitis Virus (TMEV) causes a neuroparalytic disease of commercial turkeys, expressed in paresis, incoordination, drooping wings and mortality that is controlled by vaccination. The molecular diagnosis using brain tissue RNA has now been upgraded by the development of a diagnostic dual-gene multiplex real-time PCR targeting the envelope and the non-structural NS5 gene, increasing the sensitivity by 10-100-fold compared to the previously existing assays. Based on the recent complete sequences of five TMEV isolates we have now developed a Differentiating Infected from Vaccinated Animals (DIVA) assay, to distinguish between wild-type TMEV strains and the vaccine virus. The DIVA assay was evaluated on commercial vaccines produced by two manufacturers, on RNA purified from brains of experimentally infected turkeys with TMEV strains, and on clinical samples collected between the years 2009 and 2015. We also investigated turkey feather pulps for their suitability to serve for TMEV detection, to avoid invasive sampling and bird killing. The parallel TMEV diagnosis in brain and feather-pulp RNA were similarly useful for diagnosis, at least in experimentally infected turkeys and in three cases of disease encountered in commercial flocks.

Differential diagnosis of fowlpox and infectious laryngotracheitis viruses in chicken diphtheritic manifestations by mono and duplex real-time polymerase chain reaction.

Infectious laryngotracheitis virus (ILTV) and fowlpox virus (FPV) cause diphtheritic lesions in chicken tracheas and can simultaneously infect the same bird. A differential molecular diagnostic test, the duplex real-time polymerase chain reaction, is now reported using ILTV and FPV vaccine viruses and clinical samples from chickens, either uninfected or naturally infected with ILTV or FPV, or with both viruses. The dual virus amplification by real-time polymerase chain reaction was demonstrated to behave similarly to monoplex amplification, in spite of the fact that the real-time exponential amplification plots of the vaccine viruses were more illustrative than those of the clinical samples.

Development of a reliable dual-gene amplification RT-PCR assay for the detection of Turkey Meningoencephalitis virus in Turkey brain tissues.

The Turkey Meningoencephalitis virus (TMEV) causes neuroparalytic signs, paresis, in-coordination, morbidity and mortality in turkeys. In parallel to the increased worldwide scientific interest in veterinary avian flaviviruses, including the Bagaza, Tembusu and Tembusu-related BYD virus, TMEV-caused disease also reemergence in commercial turkeys during late summer of 2010. While initially TMEV was detected by NS5-gene RT-PCR, subsequently, the env-gene RT-PCR was employed. As lately several inconsistencies were observed between the clinical, serological and molecular detection of the TMEV env gene, this study evaluated whether genetic changes occurred in the recently isolated viruses, and sought to optimize and improve the direct TMEV amplification from brain tissues of affected turkeys. The main findings indicated that no changes occurred during the years in the TMEV genome, but the PCR detection sensitivities of the env and NS5 genes differed. The RT-PCR and RNA purification were optimized for direct amplification from brain tissues without pre-replication of clinical samples in tissue cultures or in embryonated eggs. The amplification sensitivity of the NS5-gene was 10-100 times more than the env-gene when separate. The new dual-gene amplification RT-PCR was similar to that of the NS5 gene, therefore the assay can be considered as a reliable diagnostic assay. Cases where one of the two amplicons would be RT-PCR negative would alert and warn on the virus identity, and possible genetic changes. In addition, the biochemical environment of the dual-gene amplification reaction seemed to contribute in deleting non-specific byproducts that occasionally appeared in the singular RT-PCR assays on RNA purified from brain tissues.

Isolation and identification of highly pathogenic avian influenza virus subtype H5N1 from emus from the Ein Gedi oasis by the Dead Sea.

An avian influenza virus (AIV), A/Emu/Israel/552/2010/(H5N1), was isolated from a dead emu that was found in the Ein Gedi oasis near the Dead Sea. The virus molecular characterization was performed by reverse transcriptase-polymerase chain reaction (RT-PCR) and real-time RT-PCR using AIV subtype-specific primers. The virus was of high pathogenicity, according to its intravenous pathogenicity index of 2.85 and the nucleotide sequencing at the cleavage site of the hemagglutinin gene, GERRRKKR, which is typical for highly pathogenic chicken influenza A viruses.

Cytokine production in Linomide-treated nod mice and the potential role of a Th (1)/Th(2) shift on autoimmune and anti-inflammatory processes.

Linomide prevents the development of autoimmune insulitis and insulin-deficient diabetes mellitus in female NOD mice. Linomide prevents development of autoimmune manifestations in other experimentally induced and spontaneous autoimmune diseases as well, but the mechanism of action is unknown. The present report summarizes our investigations on the effect of Linomide on different functional T cell subsets in NOD mice analyzed according to their cytokine profile. Supernatants from cultured splenocytes and peritoneal cells taken from Linomide-treated mice contained lower levels of TNFalpha, IL-1 beta, IFN gamma and IL-12 versus higher levels of IL-4, IL-6 and IL-10 in comparison with supernatants from cultures of untreated mice. Our results suggest that regulation of autoimmunity following oral Linomide administration in NOD mice induces a shift from Th(1) to Th(2) phenotype response, thereby preventing the development of diabetes by active cytokine-induced immunoregulation of T cell subsets, including downregulation of Th(1) and upregulation of Th(2).